Cardiolipin: a proton trap for oxidative phosphorylation

The role of specific lipid structures in biological membranes has been elusive. There are hundreds of them in nature. Why has nature made them? How do they aid in the functioning of membrane proteins? Genetics with its ‘knock out’ organisms declares that functions persist in the absence of any parti...

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Bibliographic Details
Published in:FEBS Letters 2002-09, Vol.528 (1), p.35-39
Main Authors: Haines, Thomas H, Dencher, Norbert A
Format: Article
Language:English
Subjects:
Cardiolipin
Cardiolipin pK
Cardiolipins - chemistry
Cardiolipins - metabolism
Chemiosmotic
CL, cardiolipin
cl-, cardiolipin-less
dCL, 2′-deoxy-cardiolipin
Deoxy-cardiolipin
Hydrogen-Ion Concentration
Lipid Bilayers - metabolism
Membranes - metabolism
Mitochondria
Models, Biological
NAO, nonyl acridine orange
Oxidative Phosphorylation
PC, phosphatidyl choline
Protein Binding
Proton Pumps - metabolism
Protons
Raft
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Summary:The role of specific lipid structures in biological membranes has been elusive. There are hundreds of them in nature. Why has nature made them? How do they aid in the functioning of membrane proteins? Genetics with its ‘knock out’ organisms declares that functions persist in the absence of any particular lipid. Nonetheless some lipids, such as cardiolipin (CL), are associated with particular functions in the cell. It may merely expand the variety of culture conditions (pH, temperature, etc.) under which the wild-type organism survives. This article explores a unique role of CL as a proton trap within membranes that conduct oxidative phosphorylation and therefore the synthesis of ATP. CL’s pK 2 (above 8.0) provides a role for it as a headgroup proton trap for oxidative phosphorylation. It suggests why CL is found in membranes that pump protons. The high pK 2 also indicates that the headgroup has but one negative charge in the neutral pH range. Data on the binding of CL to all of the oxidative phosphorylation proteins suggest that the CL may aggregate the oxidative phosphorylation proteins into a patch while it restricts pumped protons within its headgroup domain – supplying protons to the ATP synthase with minimal changes in the bulk phase pH.
ISSN:0014-5793
1873-3468
DOI:10.1016/S0014-5793(02)03292-1